Tissue microchimerism is increased during pregnancy: a human autopsy study.

Microchimerism is the occurrence of small populations of cells with a different genetic background within an individual. Tissue microchimerism is considered to be primarily pregnancy-derived and is often studied relative to female-dominant autoimmune diseases, pregnancy complications, malignancies, response to injury, and transplantation outcomes. A particular distribution pattern of chimeric cells across various organs was recently described in a model of murine pregnancies. Our aim was to determine the frequency and distribution of tissue microchimerism across organs during and after pregnancy in humans. We performed in situ hybridization of the Y chromosome on paraffin-embedded autopsy samples of kidneys, livers, spleens, lungs, hearts and brains that were collected from 26 women who died while pregnant or within 1 month after delivery of a son. Frequencies of chimeric cells in various tissues were compared with those of a control group of non-pregnant women who had delivered sons. Tissue microchimerism occurred significantly more frequently in the lungs, spleens, livers, kidneys and hearts of pregnant women compared with non-pregnant women (all P < 0.01). We showed that some of the chimeric cells were CD3+ or CD34+. After correction for cell density, the lung was most chimeric (470 Y chromosome-positive nuclei per million nuclei scored), followed by the spleen (208 Y+/10(6) nuclei), liver (192 Y+/10(6) nuclei), kidney (135 Y+/10(6) nuclei), brain (85 Y+/10(6) nuclei) and heart (40 Y+/10(6) nuclei). Data from this unique study group of women who died while pregnant or shortly after delivery provide information about the number and physiologic distribution of chimeric cells in organs of pregnant women. We demonstrate that during pregnancy, a boost of chimeric cells is observed in women, with a distribution across organs, that parallels findings in mouse models.

From Glomerular Endothelium to Podocyte Pathobiology in Preeclampsia: a Paradigm Shift.

Preeclampsia is a pregnancy-specific syndrome characterized by renal dysfunction and high blood pressure. When evaluated with light microscopy, the renal lesion of preeclampsia is marked by endothelial cell swelling and the appearance of bloodless glomeruli. However, regarding the pathobiology of renal damage in preeclampsia, attention recently has shifted from the glomerular endothelial cells to the podocytes. The angiogenic imbalance in preeclampsia plays a key role in the development of both podocyte and endothelial damage in the glomerular filtration barrier. Here, we review the latest studies on the role of podocytes in the development of renal damage in preeclampsia and on podocytes as potential targets for diagnosis, treatment, and prevention of long-term complications of preeclampsia.

Association of preeclampsia with podocyte turnover.

BACKGROUND AND OBJECTIVES: Preeclampsia is characterized by hypertension and proteinuria, and increased shedding of podocytes into the urine is a common finding. This finding raises the question of whether preeclamptic nephropathy involves podocyte damage. This study examined podocyte-related changes in a unique sample of renal tissues obtained from women who died of preeclampsia. DESIGN, SETTING, PARTICIPANTS, & MEASUREMENTS: All patients with preeclampsia who died in The Netherlands since 1990 and had available autopsy tissue were identified using a nationwide database of the Dutch Pathology Registry (PALGA). This resulted in a cohort of 11 women who died from preeclampsia. Three control groups were also identified during the same time period, and consisted of normotensive women who died during pregnancy (n=25), and nonpregnant controls either with (n=14) or without (n=13) chronic hypertension. Glomerular lesions, including podocyte numbers, podocyte proliferation, and parietal cell activation, were measured. RESULTS: Patients with preeclampsia had prominent characteristic glomerular lesions. The results showed that the number of podocytes per glomerulus did not differ significantly between the patients with preeclampsia and the control groups. However, preeclampsia was associated with a significant increase in intraglomerular cell proliferation (7.3% [SD 9.4] of the glomeruli of patients with preeclampsia had Ki-67-positive cells versus 1.6% [SD 3.3] of the glomeruli of hypertensive controls and 1.1% [SD 1.3] of nonpregnant controls; P=0.004) and activated parietal epithelial cells on a podocyte location (34% [SD 13.1] of the glomeruli of patients with preeclampsia versus 18.0% [SD 15.3] of pregnant controls, 11.9% [SD 13.2] of hypertensive controls, and 10.8% [SD 13.4] of nonpregnant controls; P=0.01). CONCLUSIONS: These findings suggest that the recently described mechanisms of podocyte replacement play a role in preeclampsia. These results provide key new insights into the pathogenesis of preeclamptic nephropathy, and they open new possibilities for developing therapeutic modalities.

Preeclampsia is associated with the presence of transcriptionally active placental fragments in the maternal lung.

Preeclampsia is associated with increased levels of the circulating antiangiogenic factor sFlt-1 and with an excessive shedding of placenta-derived multinucleated syncytial aggregates into the maternal circulation. However, it remains unclear whether these aggregates are transcriptionally active in the maternal organs and can, therefore, contribute to the systemic manifestations of preeclampsia. In this study, we measured placental soluble fms-like tyrosine kinase-1 (sFlt-1) mRNA levels in preeclamptic- and control placentas and performed RNA in situ hybridization to localize the main placental expression site of sFlt-1 mRNA. Because the maternal lung is the first capillary bed that circulating syncytial aggregates traverse, we studied the presence and persistence of placental material in lungs of preeclamptic and control subjects. To confirm the placental origin of these aggregates in maternal lungs, immunohistochemistry for the placenta-specific marker hCG (human chorionic ghonadotropin) and Y chromosome in situ hybridization were performed. Using human placental tissue, we found that syncytial knots are the principal site of expression of the antiangiogenic factor sFlt-1. In addition, autopsy material obtained from women with preeclampsia (n=9) showed significantly more placenta-derived syncytial aggregates in the lungs than in control subjects (n=26). Importantly, these aggregates still contained the antiangiogenic factor sFlt-1 after their entrapment in the maternal lungs. The current study confirms the important role of syncytial knots in placental sFlt-1 mRNA production. In addition, it shows a significant association between preeclampsia and larger quantities of sFlt-1 containing syncytial aggregates in maternal lungs, suggesting that the transfer of syncytial aggregates to the maternal compartment may contribute to the systemic endothelial dysfunction that characterizes preeclampsia.

Quantitative polymerase chain reaction-based analysis of podocyturia is a feasible diagnostic tool in preeclampsia.

Preeclampsia is a significant cause of maternal and fetal morbidity and mortality worldwide. A clinically useful screening test that can predict development of preeclampsia at an early stage is urgently needed. The detection of podocyturia by immunohistochemistry after cell culture has been noted as a reliable marker for preeclampsia. However, this method is laborious and carries the risk of cell culture contamination. The aim of this study was to investigate the diagnostic value of quantitative polymerase chain reaction as a rapid method to detect preeclampsia. Clean-catch urine samples were collected from preeclamptic (n=35), healthy pregnant (n=34), and healthy nonpregnant (n=12) women. Furthermore, a control group of women with gestational hypertension (n=5) was included. Quantitative polymerase chain reaction analysis was performed for podocyte-specific markers. Receiver operating characteristic curve analyses were performed. Significantly elevated mRNA levels of nephrin, podocin, and vascular endothelial growth factor were detected in preeclamptic women compared with healthy pregnant and healthy nonpregnant controls. In addition, significantly elevated levels of nephrin mRNA were detected in urine of preeclamptic women compared with women with gestational hypertension. A positive correlation (ρ=0.82; P<0.0001) was observed between nephrin and vascular endothelial growth factor mRNA levels in preeclamptic women. Receiver operating characteristic curve analyses demonstrated a strong ability of this method to discriminate between the different study groups. Quantitative polymerase chain reaction analysis of podocyte-specific molecules in urine samples is a rapid and reliable method to quantify podocyturia. We demonstrate that this method distinguishes preeclamptic patients from healthy controls and women with gestational hypertension. This method may be a tool for the detection of preeclampsia at an earlier stage, thereby preventing maternal and fetal morbidity and mortality.